Organic superacids, polymers derived from organic superacids, and methods of making and using the same

ABSTRACT

One embodiment of the invention contemplates a proton exchange membrane for use in a variety of fuel cells. The proton exchange membrane may comprise a solid phase organic based copolymer material in which a first structural unit is derived from a polymerizable organic super acid. The organic super acid may comprise an acid group such as a sulfonic acid group or a carboxylic acid group.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No. 12/136,979filed Jun. 11, 2008, which claims the benefit of U.S. ProvisionalApplication Ser. No. 60/943,744 filed on Jun. 13, 2007.

TECHNICAL FIELD

The field to which the disclosure generally relates includes cationexchange or cation conductive materials such as fuel cell electrolytelayers, products including fuel cell electrolyte layers, copolymersderived from organic superacids, and methods of making and using thesame.

BACKGROUND

Monomers and prepolymers may be polymerized to make a variety ofproducts. In some cases, it may be desirable to provide a polymermaterial having proton conductivity.

Many fuel cells are provided with an electrolyte layer that issandwiched between an anode and a cathode, the assembly being known as amembrane-electrode assembly (MEA). In a proton exchange membrane (PEM)fuel cell, the electrolyte layer generally comprises a proton conductingsolid phase polymer electrolyte and is often called an ion-exchangemembrane or a proton exchange membrane. These polymer membranes aredesigned with the goal of accomplishing several functions thatcontribute to the overall operation of a PEM fuel cell, such asproviding a conductive pathway for protons to migrate from the anode tothe cathode, providing an electrical insulator between the anode and thecathode, and providing a gas impermeable layer that keeps the reactantgases separate and concentrated at their respective electrodes, to namebut a few. Furthermore, the types of electrolytes associated with PEMfuel cells may be incorporated into direct methanol fuel cells (DMFC)due to similar operating conditions.

SUMMARY OF EXEMPLARY EMBODIMENTS OF THE INVENTION

In one embodiment of the invention, a proton exchange membrane maycomprise an organic based polymer material that comprises a structuralunit derived from an organic superacid that includes at least two acidgroups. The acid groups may comprise a sulfonic acid group, a carboxylicacid group, a phosphonic acid group, or any other acid group that mayhave a structure which promotes intramolecular hydrogen bonding.

Other exemplary embodiments of the invention will become apparent fromthe detailed description provided hereinafter. It should be understoodthat the detailed description and specific examples, while disclosingexemplary embodiments of the invention, are intended for purposes ofillustration only and are not intended to limit the scope of theinvention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a product according to one embodiment of theinvention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

The following description of the embodiment(s) is merely exemplary innature and is in no way intended to limit the invention, itsapplication, or uses.

It is contemplated that an organic based proton exchange membranecomprising a solid phase organic based polymer material may beincorporated into various types of fuel cells to serve as an electrolytelayer situated between an anode layer and a cathode layer. In oneembodiment, fuel cell performance may be enhanced by providing anorganic based proton exchange membrane that exhibits improved protonconductivity at a low relative humidity. Allowing fuel cells to operateat a low relative humidity may reduce the problems associated withcathode flooding, water management and freeze start up, and possiblylower the cost of operating a fuel cell.

A variety of properties associated with the organic based polymermaterial that constitutes the organic based proton exchange membrane maycontribute to an elevated and maintainable volumetric density ofsolvated protons which ultimately provides for improved protonconductivity. These properties may include one or more of, for instance,the presence of one or more high acidity acid groups represented by arelatively high acid dissociation constant (pK_(a)), the presence of oneor more acid groups capable of deprotonating at a relatively low molarratio of water to acid sites (λ), or a low molar volume of the acidmoiety.

In one embodiment, a PEM fuel cell may comprise an organic based protonexchange membrane comprising a solid phase organic based copolymermaterial comprising at least one structural unit derived from a organicsuperacid capable of undergoing a polycondensation reaction with asecond monomer. The term “superacid” as used herein means an acid havingan acidity greater than 100% sulfuric acid. In one embodiment, thesuperacid may have two or more acid groups, such as a super diacid. Inanother embodiment, a plurality of organic super diacid structural unitsmay be polymerized with a plurality of suitable and indistinguishablemonomer units, or a mixture of suitable and chemically distinguishablemonomer units, to form an alternating, random, or block copolymerstrand. In another embodiment, a plurality of organic super diacidstructural units may be present in hydrophilic polymer block segmentsthat are subsequently linked with one or more suitable hydrophobicmonomers or polymer block segments to form a linear or branched n-blockcopolymer strand where n≧2. In one embodiment, a triblock copolymerstrand may include any linear arrangement of a hydrophilic organic superdiacid polymer block segment linked between a first hydrophobic polymerblock segment and a second hydrophobic polymer block segment. In yetanother embodiment, several hydrophilic organic super diacid polymerblock segments may be linked with multiple hydrophobic polymer blocksegments to form a random multiblock copolymer strand. Additionally, itis possible to form an organic based proton exchange membrane comprisinga polymer material that has a monodispersed polymer compositioncomprising the alternating, random, n-block, or multiblock copolymerstrands mentioned above. A method for producing a polymer materialsuitable for use as a proton exchange membrane that comprises copolymerstrands synthesized in part from a plurality of organic super diacidstructural units will be discussed in more detail at a later point. Theparticular organic super diacids suitable for use in such a method willnow be described.

In one embodiment, an organic super diacid structural unit may bederived from an organic super diacid characterized by a strong acidityand capable of participating in a polycondensation reaction. The strongacidity may be attributed wholly or in-part to a molecular structurethat promotes strong intramolecular hydrogen bonding between two acidgroups in close spatial proximity. This hydrogen bonding may besupplemented by the positioning of OH, or other useful groups, in thediacid structure. Acidity may be further enhanced by molecularstructures having electron withdrawing groups (EWG) linking the phenylgroups of the diacids. The strong acidity exhibited by the organic superdiacid contributes to the ability of the super diacid to deprotonate atrelatively low molar ratios of water to acid sites (λ). Examples ofsuitable acid groups include, but are not limited to, a sulfonic acidgroup, a carboxylic acid group, and a phosphonic acid group. Shown belowis a general structure representing a multitude of organic super diacidsthat promote significant intramolecular hydrogen bonding and are capableof participating in a polycondensation reaction.

In one embodiment, A may be a sulfonic acid group (—SO₃H), carboxylicacid group (—COOH), or phosphonic acid group (—PO₃H₂); Z may be anylinking atom or group such as SO₂ or CO; and Y′ may be an oxygen atom(—O—), a sulfur atom (—S—), or a direct linkage between the two rings.In another embodiment, the 2,3,7, and 8 positions of the super diacidmay comprise any group that functions, either directly or through asubsequent reaction mechanism, to render the super diacid receptive to acopolymer synthesis reaction. For copolymer synthesis by apolycondensation reaction, suitable groups include H, OH, SH, or groupsprone to nucleophilic displacement, like halides or NO₂. Otherfunctional groups, such as vinyl or oxirane, may be used for freeradical copolymerization of the super diacid. Furthermore, the 1 and 9positions may be bonded to H or a similar electropositive group.

In one embodiment, the organic super diacid may bephenoxathiin-4,6-disulfonic acid 10,10-dioxide (PHX) (named according toIUPAC rules), which is shown below with dashed lines representingintramolecular hydrogen bonding.

However, for purposes of being consistent in the specification andclaims herein the carbons will be numbered clockwise so that the abovedescribed super diacid will be referred to as followsphenoxathiin-1,9-disulfonic acid 5,5-dioxide (PHX) which is shown belowwith dashed lines representing intramolecular hydrogen bonding.

In another embodiment, the organic super diacid may bethianthrene-1,9-disulfonic acid 5,5-dioxide (THA), which is shown belowwith dashed lines representing intramolecular hydrogen bonding.

In still another embodiment, the organic super diacid may bedibenzo[b,d]thiophene-1,9-disulfonic acid 5,5-dioxide (DBT), which isshown below with dashed lines representing intramolecular hydrogenbonding.

The ability of the organic super diacids listed above to deprotonate atlow molar ratios of water to acid sites was simulated according to theBeck-3-Lee-Yang-Par hybrid density functional with the 6-311G(p,d) basisset (B3LYP//6-311G(d,p) model chemistry). The validity of the B3LYPsimulation calculation and its results were substantiated by identicalcalculations using the same model chemistry for bothtrifluoromethanesulfonic acid and sulfuric acid, both of which haveestablished λ thresholds based on different model chemistries andexperimental calculations. The results of the simulations were comparedagainst known λ thresholds for both trifluoromethanesulfonic acid andsulfuric acid and were found to be fairly similar, thus confirming theappropriateness of the B3LYP calculation and its parameters.

Through the B3LYP calculations, it was possible to determine theequilibrium conformations of the PHX, THA, and DBT diacids wheninteracting with small water clusters, such as 0≦λ≦4, and to establishthe molar ratio of water to acid sites required for deprotonation.Generally, as between two acids, the acid with a lower λ threshold isthe stronger the acid because it can deprotonate in the presence of lesswater than the acid with the higher λ threshold. Of the three organicsuper diacids, PHX was found to be the strongest acid possessing a λvalue of 1.0. Furthermore, to put the λ value of PHX into context, the λvalues of benzenesulfonic acid and trifluoromethanesulfonic acid werecalculated to be 5.0 and 3.0, respectively. And both sulfuric acid andtritluoromethanesulfonic are generally regarded as very strong acids.

Additionally, pK_(a) values were calculated for the above describedorganic super diacids using the semi-empirical continuum solvation modelCOSMO, which is a statistical thermodynamic treatment of continuumsolvation. To verify these results, this model was used to calculate thepK_(a) values of numerous acids that have known pK_(a) values based onexperimental procedures. The relationship between the calculated pK_(a)values and the published experimental values were sufficientlycorrelated and the model was deemed to be an accurate and satisfactorymeasure of the pK_(a) values of the organic super diacids. Thecalculated pK_(a) values of PHX, THA, and DBT were −6.6, −8.8, and −8.1,respectively. For contextual purposes only, the calculated pK_(a) valuesof sulfuric acid, methanesulfonic acid, and phenylsulfonic acid were−4.8, −1.7 and −2.0, respectively. These calculated values were found tobe in good agreement with corresponding experimental values of −3.0,−2.6 and −2.6, respectively.

The organic super diacids just discussed may be modified to includealcohol groups located either meta-, para-, or meta- and para- to thegroup represented by Z in the general organic super diacid structureshown earlier. The addition of alcohol groups to the organic superdiacid may provide for additional intramolecular hydrogen bonding, aswell as linkage sites suitable for polymerization by a condensationreaction. It should be noted that the number and position of any alcoholgroups may affect the characteristics of the super diacid with regardsto polymerization. For instance, while it is feasible for any alcoholgroup to participate in a condensation reaction, the acidity of thesuper diacid is stronger when two alcohols are preserved adjacent to thebridge between the phenols following polymerization. Furthermore,polymerization reactions involving super diacids with alcohol groups atthree or four positions (three or more alcohol sites) may promotecrosslinking between polymers which can reduce membrane swelling andenhance mechanical strength and resiliency. However, on the other hand,polymerization reactions involving super diacides with alcohol groups attwo positions may produce linear polymers without crosslinks which leadsto improved solubility and enhanced film forming properties. The generalstructure of the readily polymerizable organic super diacid shown beforeis reproduced below and is modified to include the possible addition ofalcohol groups.

In one embodiment, as in the earlier structure, A may be a sulfonic acidgroup (—SO₃H) a carboxylic acid group (—COOH), or phosphonic acid group(—PO₃H₂); Z may be a linking group such as SO₂ or CO; and Y′ may be anoxygen atom (—O—), a sulfur atom (—S—), or a direct linkage between thetwo rings. The B group may represent an alcohol group (—OH), a halide, achemically stable low molar volume ether group such as methyl ether(—OCH₃), isopropyl ether (—OCH(CH₃)₂), t-butyl ether (—OC(CH₃)₃),trifluoro- or trichloro-methyl ether (—OCF₃, —OCCl₃), a low molar volumeester group such as acetates (—OC(O)CH₃), or a low molar volumecarbonate such as butoxycarbonyl (—OC(O)OC(CH₃)₃). The low molar volumeof the B group helps maintain the maximum molarity of solvated protonsby minimizing the molar volume per acid hydrogen of the organic superdiacid.

In one embodiment, the organic super diacid may be3,7-dihydroxy-2,8-dimethoxyphenoxathiin-4,6-disulfonic acid10,10-dioxide (DHPHX) (named according to IUPAC rules), which is shownbelow with dashed lines representing intramolecular hydrogen bonding.

However, for purposes of being consistent in the specification andclaims herein the carbons will be numbered clockwise so that the abovedescribed super diacid will be referred to as follows2,8-dihydroxy-3,7-dimethoxyphenoxathiin-1,9-disulfonic acid 5,5-dioxide(DHPHX) which is shown below with dashed lines representingintramolecular hydrogen bonding.

In this embodiment, alcohol groups are located on each phenol ring para-to the sulfonyl bond, and methyl ether groups are located on each ringmeta- to the sulfonyl bond. However, it is understood that alternativeconfigurations are possible, such as swapping the positions of thealcohol groups with those of trifluoromethyl ether or methyl ethergroups, or substituting these methyl ether groups for two additionalalcohol groups. The corresponding molar volume per acid hydrogen ofDHPHX in this embodiment is estimated at 127 cm³.

In another embodiment, the organic super diacid may be2,8-dihydroxy-3,7-dimethoxythianthrene-1,9-disulfonic acid 5,5-dioxide(DHTHA), which is shown below with dashed lines representingintramolecular hydrogen bonding.

In still another embodiment, the organic super diacid may be2,8-dihydroxy-3,7-dimethoxydibenzo[b,d]thiophene-1,9-disulfonic acid5,5-dioxide (DHDBT), which is shown below with dashed lines representingintramolecular hydrogen bonding.

Similar to DHPHX, alternative configurations for both DHTHA and DHDBTare possible and may be utilized during polymerization to influencevarious properties of the polymer.

It should be understood by those skilled in the art that a wide varietyof polymers comprising structural units derived from the embodimentsdisclosed above, both general and specific, may be achieved. Forexample, the identity of the acid group, the number and location ofalcohol groups, and the linkage between the rings opposite the sulfonylgroup may all be varied as previously mentioned or in accordance withthe knowledge and understanding of those skilled in the art. Oneembodiment of a method of synthesis of an organic super diacid and itscorresponding polymerization will now be described with reference to anorganic super diacid of the PHX and DHPHX type. The followingdescription is not limited to the specific organic super diaciddiscussed or the corresponding polymer generated, but instead isapplicable to all general embodiments disclosed, including the organicsuper diacid of the THA and DHTHA type, and the organic super diacid ofthe DBT and DHDBT type. Furthermore, the super diacids of thisinvention, as well as the super diacids that are useful in variousembodiments of the invention, are not limited to the synthesis methodsdescribed herein.

The synthesis path may begin with the organic super diacid precursormolecule 2,3,7,8-tetramethoxyphenoxathiin (TMP). The synthesis of TMPhas been previously described in the literature and can readily bemanipulated into an appropriate PHX or DHPHX related organic superdiacid in a three or four step process, depending on the desiredoutcome. The organic super diacid may then be subsequently polymerizedinto a polymer by established methods of polycondensation. The resultingpolymer may then be incorporated into a polymer material that may beused to construct a proton exchange membrane for use in an assortment offuel cells.

The first step in forming the PHX and DHPHX related organic super diacidis to oxidize the sulfur atom in TMP to produce a sulfonyl group.Oxidation of the sulfur atom may be accomplished with a variety ofreagents known to those of skill in the art, most notably by oxone (2KHSO₅.KHSO₄.K₂SO₄), mCPBA, or hydrogen peroxide (H₂O₂). The oxidationstep is illustrated below.

After oxidizing the sulfur atom in TMP, the methyl ether groups may beremoved using NaSEt, BBr₃, or any other suitable reagent known to thoseof ordinary skill in the art. This step is illustrated below. It shouldbe noted that the methoxy groups located para to the sulfone group wouldbe cleaved faster than the ones located meta to the sulfone group. Thus,a diol compound could be obtained that would permit the chemicaldifferentiation of the two pairs of phenolic hydroxyl groups.

Following oxidation of the sulfur atom and removal of the methyl ethers,the resulting molecule may undergo sulfonation, or it may undergo anadditional step prior to sulfonation in order to modify one or morealcohol groups, if desired. If directly proceeding to sulfonation isdesired, then the molecule may be exposed to fuming sulfuric acid orsubjected to another method of electrophilic aromatic substitution toproduce an organic super diacid, as illustrated below.

The addition of sulfonic acid groups in the manner shown above occursrather easily and predictably for a number of reasons. First, thearomatic rings of the molecule that may undergo sulfonation areelectron-rich. Second, it is energetically favorable for the sulfonicacid groups to bond at the positions ortho- to the ring oxygen atom asevidenced by ab initio free energy of formation calculations performedfor each possible diacid stereoisomer. In fact, for each stereoisomer,both the enthalpy of formation and the Gibbs free energy were calculatedusing the B3LYP/6-311G(d,p) model chemistry in order to predict theprobable bonding sites for sulfonic acid groups during sulfonation. Thecalculations indicate that the stereoisomer shown above, with sulfonicacid groups located ortho- to the ring oxygen atom, is energeticallyfavored over the other possible stereoisomers by over 70 KJ/mole, andthus, would be the principal product of the sulfonation step in thismethod of diacid synthesis.

However, as mentioned earlier, it may be desirable to modify one or morealcohol groups following oxidation and the subsequent removal of themethyl ether groups. In this case, selective modification of the alcoholgroups may be achieved by exploiting the differences in the acidities ofthe alcohol groups based on their location in reference to the sulfonylgroup. In one embodiment, the alcohol groups positioned para- to thesulfonyl bond may be preferentially deprotonated in the presence of arelatively strong base because the para-alcohols are more acidic thanthe meta-alcohols. And once deprotonated, the para-positions are morenucleophilic than the meta-positions and may therefore be preferentiallyalkylated or acylated. A possible modification to the alcohol groupslocated para- to the sulfonyl bond on each ring may be the formation ofether groups comprising the ligand R¹. The molecule may then undergosulfonation by exposure to fuming sulfuric acid, or another method ofelectrophilic aromatic substitution. The two steps just described areillustrated below.

On the other hand, the free alcohol groups positioned meta- to thesulfonyl bond are more nucleophilic than the para-alcohols when notdeprotonated, thus allowing the meta-alcohols to be preferentiallyalkylated or acylated in the presence of a weak base. In thisembodiment, the alcohol groups located meta- to the sulfonyl bond oneach ring may be transformed into ether groups comprising the ligand R².The molecule may then undergo sulfonation by exposure to fuming sulfuricacid, or another method of electrophilic aromatic substitution. The twosteps just described are illustrated below.

In the above embodiments, both R¹ and R² may be chemically stable, lowmolar volume ligands such as a methyl group (—CH₃) or a trifluoromethylgroup (—CF₃). The low molar volume of the ligands helps minimize themolar volume of the diacid per acid hydrogen. Furthermore, it is stillenergetically favorable for the sulfonic acid groups to bond at thelocations ortho- to the ring oxygen atom. In fact, the presence andlocation of ether groups comprising ligands R¹ or R² has littleappreciable effect on the energetic preference of sulfonic acid groupsto bond to each ring at the location ortho- to the ring oxygen atomduring sulfonation.

While various steps in organic super diacid synthesis have beendescribed, it should be noted that polymerization is feasible prior tothe sulfonation step in which sulfonic acid groups are bonded to thearomatic rings. It is contemplated that a sulfonation step followingpolymerization would produce at most a slight hindrance in membraneconductivity because overall sulfonation at locations ortho- to thelinkage between rings and opposite the sulfonyl group would remain high.

A method of synthesizing a copolymer comprising an organic super diacidstructural unit will now be described with reference to organic superdiacids of the PHX and DHPHX type. As mentioned before, the followingdescription is not limited to the specific organic super diaciddiscussed and the corresponding copolymer generated, but may also bepracticed with the other general embodiments disclosed, including theorganic super diacid of the THA and DHTHA type, and the organic superdiacid of the DBT and DHDBT type. Furthermore, membranes derived fromsuper diacids according to various embodiments of the invention are notlimited to those produced from the polymer synthesis methods describedherein.

In one embodiment, a random copolymer strand may be formed from anorganic super diacid that comprises one or more alcohol groups capableof participating in a polycondensation reaction. For example, the randomcopolymer strand may comprise a structural unit derived from an organicsuper diacid having a functionality of up to four, as previously shown.

In the presence of a base and solvent, the organic super diacid may bepolymerized by reaction with an aromatic compound comonomer such as anaromatic dihalide, aromatic dihydroxy, aromatic dimercapto, or othersimilar compound commonly used by those skilled in the art to synthesizearomatic polyethers. The particular aromatic compound or compoundsselected for the polycondensation reaction depends on the identity ofthe functional groups or chemical groups located at the polycondensationlinkage sites of the organic super diacid, generally referred to as theB group in the general organic super diacid structure shown earlier. Thepolycondensation reaction of an organic super diacid having afunctionality of four and an aromatic dihalide comonomer is showngenerally below.

The aromatic dihalide comonomer may have a suitable leaving group. Xsuch as —F, —Cl, —Br, —NO₂, or the like, and an electron withdrawinggroup Y such as, —CO—, —SO₂—, —P(O)R—, perfluoroalkyl, andheteroaromatic rings including pyridine, oxazole, benzoxazole,quinoxaline, quinoline, oxadiazole, and the like. For example, invarious embodiments, the aromatic compound may be the aromatic dihalide4,4′-difluorodiphenylsulfone, 4,4′-dichlorodiphenylsulfone,4,4′-difluorobenzophenone, 1,3-bis(4′-fluorobenzoyl)benzene, or anyother suitable aromatic dihalide known to those skilled in the art. Theappropriate base for the polycondensation reaction may vary, but typicalexamples include sodium hydroxide (NaOH) and potassium carbonate(K₂CO₃). Similar to the base, a wide variety of solvents may alsocontribute to the polycondensation reaction, such as, but not limitedto, sulfolane, diphenylsulfone, dimethyl fluoride, dimethyl sulfoxide,dimethylacetamide, N-methylpyrrolidinone, or the like, and combinationsthereof.

The aromatic compound comonomer may have to be altered if thefunctionality of the organic super diacid is less than four because ahalide is occupying one or more of the 2, 3, 7, or 8 positions of theorganic super diacid. For example, an aromatic dihydroxy or an aromaticdimercapto may serve as the aromatic compound comonomer. In thisinstance, X would be —OH (dihydroxy), —SH (dimercapto), or a similargroup, and Y may be a group such as —O—, —S—, —CO—, —SO₂—, —P(O)R—,alkyl, perfluoroalkyl, a single bond, or heteroaromatic rings includingpyridine, oxazole, benzoxazole, quinoxaline, quinoline, oxadiazole, andthe like.

The number m of monomer structural units in the random copolymermaterial may vary depending on a multitude of factors known to thoseskilled in the art. It is also conceivable to form a copolymer materialthat comprises a mixture of monomer structural units due to differencesin the chemical identity of the electron withdrawing group Y. In thissituation, the copolymer material may comprise a plurality of organicsuper diacid structural units bonded to at least one of a variety ofmonomer structural units containing an internal ether, ketone, thio,alkyl, perfluoroalkyl, or sulfone linkage. Furthermore, it is possibleto generate a copolymer material that terminates with reactive sitessuch as NaO, —OH, —F, —Cl or the like by performing a polycondensationreaction with an excess of either the organic super diacid or the one ormore aromatic compound comonomers. The resulting copolymer with terminalreactive sites may provide a mechanism for subsequent linkage withhydrophobic polymer block segments that comprise halogenatedterminations.

Similar to the polycondensation reaction shown above for an organicsuper diacid having a polymer functionality of four, a polymer may alsocomprise a structural unit derived from one of the organic super diacidspreviously shown having a polymer functionality of less than four due tothe presence of non-functional groups located para- or meta- to thesulfonyl bond. For example, in one embodiment, the functionality of theorganic super diacid may be two. These organic super diacids may besynthesized into a similar copolymer by application of the identicalpolycondensation reaction used to link the organic super diacid having apolymer functionality of four with the aromatic compound comonomer. Thepolycondensation reaction of the organic super diacid comprisingnon-functional groups located para- to the sulfonyl bond is showngenerally below.

Also, the polycondensation reaction of the organic super diacidcomprising non-functional groups located meta- to the sulfonyl bond isshown generally below.

While each of the above embodiments described result in randomcopolymers, it is also contemplated, as mentioned before, that thoseskilled in the art are capable of manipulating the organic super diacidpolymer synthesis process to form copolymers that comprise analternating copolymer, an n-block copolymer where 2≦n≧5, or a randommultiblock copolymer. For example, commonly assigned United StatesPatent Applications 2004/0186262 filed Jan. 30, 2004 and 2006/0249444filed May 3, 2005 both disclose block copolymer teachings that may beuseful in conjunction with the organic superacids disclosed herein forfabricating organic based proton exchange membranes.

Referring now to FIG. 1, one embodiment of the invention may include afuel cell 10 including an electrolyte layer 12 comprising an organicbased proton exchange membrane fabricated from the organic polymerstructures previously discussed. The organic based proton exchangemembrane may be in various types of fuel cells, such as proton exchangemembrane fuel cells and direct methanol fuel cells.

The fuel cell 10 is an electrochemical device that combines a fuel suchas hydrogen with an oxidant such as oxygen to produce electricity. Thefuel cell 10 may include an electrolyte layer 12 sandwiched between twoelectrode layers 14, the combination being known as a membrane electrodeassembly (MEA) 15. In practice, the electrode layers 14 are furtherdefined as an anode and a cathode, both of which facilitate chemicalreactions that occur in the fuel cell 10. The anode is defined as theelectrode layer 14 that electrons flow away from and the cathode isdefined as the electrode layer 14 that electrons flow towards.

The electrode layers 14 generally may include small catalyst particlesmixed with a binder such as an ionomer. The binder serves to fix thecatalyst particles in a structure that allows for optimal contactbetween the catalyst particles contained in the electrodes 14 and theelectrolyte 12. In one embodiment, the binder may include the types oforganic super acid based copolymers disclosed herein. Platinum metalsand platinum alloys are popular examples of catalyst particles and maybe utilized as either a pure catalyst or a supported catalyst. In thecase of a supported catalyst, the small catalyst particles may be finelydivided over larger carbon or graphite support particles.

Gas diffusion layers (GDL) 18 are situated alongside the surfaces of theelectrode layers 14 that are furthest from the electrolyte layer 12.GDL's 18 serve numerous functions and may include carbon-based materialsthat render the layer porous and conductive. A GDL 18 comprises a porousmedia to assist in diffusing the reactant gases equally across theirrespective electrode layers 14, as well as to move water or any otherliquid away from the electrode layers 14. The porous media of the GDL 18is also conductive to provide an electrical pathway from the electrodelayers 14 to the current collector so that the electrons generated atthe anode can be extracted from the fuel cell 10 and eventually returnedto the cathode. A further function of the GDL 18 is to provide a basicmechanical structure for the MEA 15. Typically, carbon-based materialsthat make up a GDL 18 may include, but are not limited to, carbon cloth,non-woven pressed carbon fibers, carbon paper, or a felt-like carbonmaterial.

It is also common to add various materials to a GDL 18. For example,GDL's 18 may include a microporous layer 22 interposed between the GDL18 and the electrode layer 14 to assist in water management within afuel cell 10. A microporous layer 22 may include a binder and some othercomponent that influences the binder's affinity towards water.

To produce a useful voltage, many fuel cells 10 may be connected inseries to form a fuel cell stack. A common approach to form a fuel cellstack is to connect adjacent fuel cells 10 through a bipolar plate 20. Abipolar plate 20 may form an electrical connection 24 over a largeportion of the GDL layer 18 so as to minimize the electrical resistancethat leads to a voltage drop when an electron travels between thebipolar plate 20 and the electrode layer 14. At the same time, a bipolarplate 20 provides reactant gas flow channels 26 for separately feeding afuel to the anode and an oxidant to the cathode. To satisfy these twocompeting interests, the gas flow channels 26 are sized to allow asufficient amount of fuel or oxidant to be supplied to the electrodelayer 14 while at the same time providing adequate surface contact withthe GDL layer 18 to facilitate the transfer of electrons. A bipolarplate 20 may also include coolant flow channels 28 that can support theflow of a coolant vapor or a coolant liquid if necessary. Bipolar plates20 may include a conductive material such as, but not limited to,graphite, a polymeric carbon composite, stainless steel, aluminum,titanium, or combinations thereof.

The above description of embodiments of the invention is merelyexemplary in nature and, thus, variations thereof are not to be regardedas a departure from the spirit and scope of the invention.

1. A product comprising: a proton conductive polymer for use in a fuelcell comprising a first structural unit that has the general formula

and wherein A comprises a sulfonic acid group, a carboxylic acid group,or a phosphoric acid group; Y′ is O, S, or a direct carbon bond; eachindividual B comprises any of an alcohol, a halide, NO₂, a low molarvolume ether group, a low molar volume ester group, a low molar volumecarbonate group, or —O—; and Z is a sulfonyl group or a carbonyl group.2. The product of claim 1 wherein the low molar volume ether groupcomprises methyl ether, isopropyl ether, t-butyl ether, trifluoromethylether, or trichloromethyl ether.
 3. The product of claim 1 wherein thelow molar volume ester group comprises an ester acetate.
 4. The productof claim 1 wherein the low molar volume carbonate group comprisesbutoxycarbonyl.
 5. The product of claim 1 wherein the first structuralunit is

and wherein A comprises a sulfonic acid group.
 6. The product of claim 1wherein the first structural unit is

and wherein A comprises a sulfonic acid group.
 7. The product of claim 1wherein the first structural unit is

and wherein A comprises a sulfonic acid group; and R comprises a lowmolar volume ligand to form a low molar volume ether group, a low molarvolume ester group, or a low molar volume carbonyl group.
 8. The productof claim 7 wherein the low molar volume ligand is CH₃, CH(CH₃)₂,C(CH₃)₃, CF₃, CCl₃, C(O)CH₃, or C(O)OC(CH₃)₃.
 9. The product of claim 1wherein the first structural unit is

and wherein A comprises a sulfonic acid group; and R comprises a lowmolar volume ligand to form a low molar volume ether group, a low molarvolume ester group, or a low molar volume carbonyl group.
 10. Theproduct of claim 9 wherein the low molar volume ligand is CH₃, CH(CH₃)₂,C(CH₃)₃, CF₃, CCl₃, C(O)CH₃, or C(O)OC(CH₃)₃.
 11. The product of claim 1wherein the proton conductive polymer is a proton conductive copolymerfurther comprising a second structural unit that has the general formula

and wherein Y comprises an electron withdrawing group.
 12. The productof claim 11 wherein the electron withdrawing group comprises —O—, —S—,—CO—, —SO₂—, —POR—, an alkyl group, a perfluoroalkyl group, or aheteroaromatic ring.
 13. The product of claim 12 wherein theheteroaromatic ring comprises pyridine, oxazole, benzoxazole,quinoxaline, or oxadiazole.
 14. The product of claim 11 wherein theproton conductive copolymer has the general formula

and wherein A comprises a sulfonic acid group; and Z comprises asulfonyl group.
 15. The product of claim 11 wherein the protonconductive copolymer has the general formula

and wherein A comprises a sulfonic acid group; and Z comprises asulfonyl group.
 16. The product of claim 11 wherein the protonconductive copolymer has the general formula

and wherein A comprises a sulfonic acid group; and R¹ comprises a lowmolar volume ligand to form a low molar volume ether group, a low molarvolume ester group, or a low molar volume carbonyl group.
 17. Theproduct of claim 16 wherein the low molar volume ligand is CH₃,CH(CH₃)₂, C(CH₃)₃, CF₃, CCl₃, C(O)CH₃, or C(O)OC(CH₃)₃.
 18. The productof claim 12 wherein the proton conductive copolymer has the generalformula

and wherein A comprises a sulfonic acid group; R² comprises a low molarvolume ligand to forms a low molar volume ether group, a low molarvolume ester group, or a low molar volume carbonyl group.
 19. Theproduct of claim 18 wherein the low molar volume ligand is CH₃,CH(CH₃)₂, C(CH₃)₃, CF₃, CCl₃, C(O)CH₃, or C(O)OC(CH₃)₃.
 20. (canceled)21. (canceled)
 22. (canceled)
 23. (canceled)
 24. (canceled) 25.(canceled)
 26. (canceled)
 27. (canceled)
 28. (canceled)
 29. (canceled)30. (canceled)
 31. (canceled)
 32. (canceled)
 33. (canceled)